Dynamical mass generation and critical behavior in pseudo-Proca quantum electrodynamics

Abstract

We investigate dynamical mass generation in pseudo-Proca quantum electrodynamics (PPQED) by means of Schwinger--Dyson equations in rainbow-quenched and unquenched truncations. The pseudo-Proca screening scale m, together with the fine-structure constant α, the flavor number N, and the ultraviolet cutoff Λ, control the critical thresholds for chiral symmetry breaking in the reduced (2+1)D theory. Within these truncation schemes, we obtain analytical estimates for both the critical coupling αc(m,Λ) and the critical number of fermion flavors Nc(m,Λ,g), and show that increasing m suppresses dynamical mass generation through Yukawa screening. We further assess the robustness of this physical picture by incorporating a Ball--Chiu vertex construction, which modifies the quantitative values of the critical parameters while preserving their qualitative dependence on the screening scale m. In addition, within the static approximation, the anisotropic extension indicates that the critical coupling decreases as the ratio vF/c increases. Taken together, our results suggest that the scale m plays an important role in modulating criticality in PPQED. Furthermore, the Ball-Chiu vertex construction shows that vertex corrections modify the quantitative values of the critical parameters while preserving the screening-driven suppression of dynamical mass generation in (2+1)D.